On the membrane translocation of diphtheria toxin: at low pH the toxin induces ion channels on cells.

Diphtheria toxin (DT) in acidic media forms ion-conducting channels across the plasma membrane and inhibits protein synthesis of both highly and poorly DT-sensitive cell lines. This results in loss of cell potassium and in entry of both sodium and protons with a concomitant rapid lowering of membrane potential. The pH dependency of the permeability changes is similar to that of the inhibition of cell protein synthesis. DT-induced ion channels close when the pH of the external medium is returned to neutrality and cells recover their normal monovalent cation content. Similar permeability changes were induced by two DT mutants defective either in enzymatic activity or in cell binding, but not with a mutant defective in membrane translocation. The implication of these findings for the mechanism of DT membrane translocation is discussed.     

Diphtheria toxin at low pH depolarizes the membrane, increases the membrane conductance and induces a new type of ion channel in Vero cells.

Receptor-dependent translocation of diphtheria toxin across the surface membrane of Vero cells was studied using patch clamp techniques. Translocation was induced by exposing cells with surface-bound toxin to low pH. Whole cell current and voltage clamp recordings showed that toxin translocation was associated with membrane depolarization and increased membrane conductance. The conductance increase was voltage independent, with a reversal potential of approximately 15 mV. This value was unaffected by changing the Cl- gradient across the membrane and microfluorometric measurements showed that the cytosolic Ca2+ concentration was only marginally elevated by the translocation. The conductance increase is thus mainly due to monovalent cations. Exposing outside-out and cell-attached patches with bound toxin to low pH induced a new type of ion channel in the membrane. The channel current was inward at negative membrane potentials and the single channel conductance was approximately 30 pS. This value is about three times larger than for receptor-independent channels induced by diphtheria toxin or toxin fragments in artificial lipid membranes.     

Selective translocation of the A chain of diphtheria toxin across the membrane of purified endosomes.

Translocation is a necessary and rate-limiting step for diphtheria toxin (DT) cytotoxicity. We have reconstituted DT translocation in a cell-free system using endosomes purified from lymphocytes and have demonstrated this using two different probe/cell systems, which provided identical results: 125I-DT/human CEM cells and 125I-transferrin-DT/mouse BW cells. The cell-free DT translocation process was found to be dependent on the presence of the pH gradient endosome (pH 5.3)/cytosol (pH 7). Among the pH equilibrating agents, nigericin (5 microM) was found to be the most effective, inhibiting DT translocation by 88%. An optimum pH value of 7 on the cytosolic side of the membrane (pH gradient approximately 1.7) was determined. ATP per se is not required for DT translocation. 125I-DT translocation was 3-fold more active from late than from early endosomes, probably because of their slightly more acidic pH. Only the A chain of the toxin was found to escape from either 125I-DT/CEM or 125I-transferrin-DT/BW endosomes. Translocation of control endosome labels (125I-transferrin and 125I-horseradish peroxidase) was never observed. We also show that DT receptors present on resistant (mouse) cells block the translocation of the toxin and are responsible for the resistance of these cells to DT.     

A point mutation of proline 308 in diphtheria toxin B chain inhibits membrane translocation of toxin conjugates

Diphtheria toxin (DT) is a soluble protein that translocates across hydrophobic lipid bilayers in response to low pH. The translocation activity of DT has been localized to the 40-kDa toxin B chain and can be expressed independently of the C-terminal receptor binding site. Buried hydrophobic domains in DT are thought to participate in the membrane translocation process. We have identified a mutant form of DT, CRM 102, that has a point mutation at position 308 (Pro----Ser) within one of these hydrophobic domains. CRM 102 conjugated to a monoclonal antibody against the T cell receptor, the transferrin receptor, or transferrin itself is approximately 10-fold less toxic than native DT or a control DT mutant, CRM 103, linked to the same binding moieties. Direct measurement of membrane translocation activity by exposure of cells to low extracellular pH demonstrates that CRM 102 conjugates express only 10% of the translocation activity of the control toxin conjugates. However, when CRM 102 or 102 conjugates bind and kill cells via the DT receptor, no reduction in membrane translocation activity is observed. The defect in CRM 102 is not evident in the presence of 20 mM NH4Cl. The defect in translocation also has no effect on the ratio of the lag time before protein synthesis inhibition begins to the rate of protein synthesis inhibition. Thus, the proline-serine substitution at position 308 disrupts the membrane translocation process and distinguishes between two routes of DT entry: DT receptor-mediated entry and entry mediated by alternate receptors.     

Distinct steps in the penetration of adenylate cyclase toxin of Bordetella pertussis into sheep erythrocytes. Translocation of the toxin across the membrane.

Adenylate cyclase (AC) toxin from Bordetella pertussis penetrates eukaryotic cells and upon activation by calmodulin generates unregulated levels of intracellular cAMP. The process of toxin penetration into sheep erythrocytes was resolved into three consecutive steps including insertion, translocation, and intracellular cleavage. Insertion of the toxin into the cell membrane occurred over a wide temperature range (4-36 degrees C). In contrast, translocation of the toxin, i.e. transfer of the NH2-terminal catalytically active fragment across the membrane, occurred only above 20 degrees C and was highly temperature-dependent. While a single exposure of the toxin to Ca2+ was sufficient for its insertion into the plasma membrane, toxin translocation required exogenous Ca2+ at mM concentrations. Translocation was not affected by pretreatment of cells with trypsin, N-ethylmaleimide, and sodium carbonate at alkaline pH. The NH2-terminal fragment of the toxin was cleaved in the cell releasing the 45-kDa active AC into the cytosol. The cleavage was blocked by treatment of cells with N-ethylmaleimide. It is hypothesized that the COOH-terminal portion of the toxin creates in the membrane a channel through which the NH2-terminal fragment is translocated.     

GPI-anchored diphtheria toxin receptor allows membrane translocation of the toxin without detectable ion channel activity.

We have investigated the role of the transmembrane and cytoplasmic domains of the diphtheria toxin (DT) receptor [heparin-binding epidermal growth factor (HB-EGF) precursor] in the intoxication pathway. Two mutants were constructed in which these domains were replaced by either a 37 amino acid sequence signalling membrane attachment via a glycosylphosphatidylinositol (GPI) anchor (DTR-GPI) or by the transmembrane and cytoplasmic domains of the human EGF receptor (DTR-EGFR). Similar amounts of DTA fragment were translocated through the plasma membrane of NIH 3T3 cells transfected with the wild-type receptor (DTR), DTR-GPI and DTR-EGFR, but translocation was about six times less efficient in the case of DTR-GPI and DTR-EGFR when taking into account the number of receptors expressed. Interestingly, DT-induced 22Na+ influx was weak in DTR-EGFR cells and not detectable in DTR-GPI cells. Whole cell patch-clamp analysis showed the DT at low pH induced depolarization and decreased input resistance in DTR cells (and to a lesser extent also in DTR-EGFR cells) but not in DTR-GPI cells. These results suggest that the transmembrane and cytoplasmic part of the receptor might be involved in channel activity and that translocation of the A fragment is independent of toxin-induced cation channel activity.     

Temporal separation of protein toxin translocation from processing events

Intoxication of Vero cells by ricin, modeccin, diphtheria toxin (DT), and Pseudomonas exotoxin A requires: 1) binding to cell surface receptors; 2) transport to the cytoplasm; and 3) enzymatic inactivation of a component of the protein synthetic machinery. The kinetic profiles of all four toxins consist of a lag followed by the apparent first-order decrease in protein synthesis. Autoradiographic analysis of DT-intoxicated cell populations has demonstrated that two subpopulations of cells exist during the period of decreasing protein synthesis: one population synthesizing at control levels and the other synthesizing little or no protein (Hudson, T. H., and Neville, D. M., Jr. (1985) J. Biol. Chem. 260, 2675-2680). The present study correlates the autoradiographic data with the rates of protein synthesis decline in cells intoxicated with modeccin, ricin, Pseudomonas exotoxin A, as well DT. In all cases, the first time point which exhibits a decrease in protein synthetic activity also exhibits two subpopulations of cells, one synthesizing protein at control rates and the other synthesizing little or no protein. As the intoxication progresses, cells leave the control population by the rapid cessation of all protein synthesis. These experiments demonstrate that transport of all four toxins to the cytosol is the rate-limiting step during the pseudo first-order decline in protein synthesis. Furthermore, the final step in the transport process (translocation) must result in the release to the cytoplasm of a quantity of toxin sufficient to rapidly inactivate all protein synthesis in that cell. The probability of a translocation event occurring in any cell of the population is established during the lag and remains constant throughout the first-order decrease in protein synthesis. The requirement for acidification during the intoxication by DT, Pseudomonas exotoxin A, or modeccin is restricted to the lag period. Acidification is therefore necessary to establish the probability of translocation, but it is not directly involved in the actual translocation of these toxins. The pseudo first-order passage of DT intoxications through antitoxin and NH4Cl- or monensin-sensitive stages are shown to have the same cellular basis as the pseudo first-order decrease in protein synthesis. A kinetic model is presented which defines the DT intoxication process from one of its earliest events (endocytosis) to its penultimate event (translocation of toxin to the cytosol).(ABSTRACT TRUNCATED AT 400 WORDS)     

Dual effects of the ricin A chain on protein synthesis in rabbit reticulocyte lysate. Inhibition of initiation and translocation

Ricin A chain caused inhibition of protein synthesis by reticulocyte lysate with concomitant depurination of 28S rRNA. The partial reaction(s) of protein synthesis inhibited was investigated by following the appearance of [35S]methionine from initiator [35S]Met-tRNA into 40S ribosomal subunits, 80S monosomes and polysomes. Ricin A chain caused an accumulation of [35S]Met in monosomes which did not enter polysomes. In these respects the effects of the ricin A chain resembled those of diphtheria toxin, an inhibitor of elongation-factor-2-catalyzed translocation. This is consistent with the previously proposed site of action of ricin as an inhibitor of elongation. However, the inhibitory effects of the ricin A chain and diphtheria toxin are not equivalent because we observed that the rate of formation of the 80S initiation complex was reduced approximately sixfold with the ricin A chain relative to diphtheria toxin. Analysis of methionine-containing peptides bound to 80S monosomes in ricin-A-chain-inhibited and diphtheria-toxin-inhibited lysates, programmed with globin mRNA, revealed a predominance of Met-Val, suggesting that the elongation cycle is inhibited at the translocation step. Translocation was also implicated as the step blocked in both the ricin-A-chain-inhibited and diphtheria-toxin-inhibited lysates, by the finding that nascent peptide chains were unreactive towards puromycin. It is concluded that ricin-A-chain-modified ribosomes are deficient in two protein synthesis partial reactions: the formation of the 80S initiation complex during initiation and the translocation step of the elongation cycle.     

Quantal entry of diphtheria toxin to the cytosol

The rate-limiting step in diphtheria toxin (DT) intoxication of Vero cells has been determined utilizing cycloheximide as an inhibitor of the intoxication process. Cycloheximide is shown to inhibit the toxin catalyzed ADP-ribosylation of elongation factor 2 (EF-2). The inhibition is blocked by puromycin thus establishing the ribosome as the location of cycloheximide protection. Washing cells free of cycloheximide rapidly reverses the protective effect. The initial rates of protein synthesis inhibition observed after removal of cycloheximide from DT-intoxicated cells are 5 to 12-fold greater than rates observed in unprotected cells and are shown to reflect ADP-ribosylation of EF-2 by cytosolic DT. Ten to thirty minutes after cycloheximide removal, the rate of protein synthesis inhibition abruptly changes to values identical to those of unprotected cells. Both the initial rates and extent of the initial rapid inactivation are directly related to toxin concentration and time of incubation with DT in the presence of cycloheximide. We concluded that: the rate-limiting step in protein synthesis inhibition by DT is not the ADP-ribosylation of EF-2 by cytosolic toxin but rather the earlier entry step of DT into the cytosol. DT enters the cytosol as a bolus of sufficient size to rapidly inactivate all EF-2 in that cell. It is inferred from 1 and 2 that the first order inactivation rate exhibited by DT is the result of the probability of the release of a bolus of toxin to the cytosol of any cell in the population per unit time. Autoradiographic analysis of intoxicated cell populations support this two-population state model. The size of a single bolus or quantum of DT is calculated from data over the range of 10(-11) to 10(-9) M DT and is found to remain constant. We suggest that the cytosolic entry mechanism of DT results from a unique ability of the internalized toxin molecules to destabilize the vesicular membrane resulting in a random release of a bolus of toxin into the cytosol. Because the bolus size remains constant over a 50-fold change in receptor occupancy the possibility is raised that DT undergoes a post-receptor packaging process, package size remaining a constant and package number increasing with receptor occupancy.     

Oligomerization of membrane-bound diphtheria toxin (CRM197) facilitates a transition to the open form and deep insertion

Diphtheria toxin (DT) contains separate domains for receptor-specific binding, translocation, and enzymatic activity. After binding to cells, DT is taken up into endosome-like acidic compartments where the translocation domain inserts into the endosomal membrane and releases the catalytic domain into the cytosol. The process by which the catalytic domain is translocated across the endosomal membrane is known to involve pH-induced conformational changes; however, the molecular mechanisms are not yet understood, in large part due to the challenge of probing the conformation of the membrane-bound protein. In this work neutron reflection provided detailed conformational information for membrane-bound DT (CRM197) in situ. The data revealed that the bound toxin oligomerizes with increasing DT concentration and that the oligomeric form (and only the oligomeric form) undergoes a large extension into solution with decreasing pH that coincides with deep insertion of residues into the membrane. We interpret the large extension as a transition to the open form. These results thus indicate that as a function of bulk DT concentration, adsorbed DT passes from an inactive state with a monomeric dimension normal to the plane of the membrane to an active state with a dimeric dimension normal to the plane of the membrane.     

Mutation of specific acidic residues of the CNF1 T domain into lysine alters cell membrane translocation of the toxin

The Rho-GTPases-activating toxin CNF1 (cytotoxic necrotizing factor 1) delivers its catalytic activity into the cytosol of eukaryotic cells by a low pH membrane translocation mechanism reminiscent of that used by diphtheria toxin (DT). As DT, CNF1 exhibits a translocation domain (T) containing two predicted hydrophobic helices (H1-2) (aa 350-412) separated by a short peptidic loop (CNF1-TL) (aa 373-386) with acidic residues. In the DT loop, the loss of charge of acidic amino acids, as a result of protonation at low pH, is a critical step in the transfer of the DT catalytic activity into the cytosol. To determine whether the CNF1 T domain operates similarly to the DT T domain, we mutated several ionizable amino acids of CNF1-TL to lysine. Single substitutions such as D373K or D379K strongly decreased the cytotoxic effect of CNF1 on HEp-2 cells, whereas the double substitution D373K/D379K induced a nearly complete loss of cytotoxic activity. These single or double substitutions did not modify the cell-binding, enzymatic or endocytic activities of the mutant toxins. Unlike the wild-type toxin, single- or double-substituted CNF1 molecules bound to the HEp-2 plasma membrane could not translocate their enzymatic activity directly into the cytosol following a low pH pulse.     

Channels formed in phospholipid bilayer membranes by diphtheria, tetanus, botulinum and anthrax toxin.

Diphtheria, tetanus, botulinum, and anthrax toxin are multipartate toxins, one of the domains of which is (or is presumed to be) an enzyme. Cell intoxication requires that the enzymatic portion gain access to the cytosol via endocytosis into an acidic vesicle compartment of the cell. Translocation of the enzyme across the vesicular membrane is dependent on the low pH of the vesicle and involves another domain of the toxin; for each of these toxins, that domain is capable of forming channels in phospholipid bilayer membranes. These channels are large (greater than 12 A diameter) and voltage-gated, and the pH conditions required for their formation in lipid bilayers are similar to those existing in acidic vesicles and required for cell intoxication.     

Dependence of ricin toxicity on translocation of the toxin A-chain from the endoplasmic reticulum to the cytosol

Ricin acts by translocating to the cytosol the enzymatically active toxin A-chain, which inactivates ribosomes. Retrograde intracellular transport and translocation of ricin was studied under conditions that alter the sensitivity of cells to the toxin. For this purpose tyrosine sulfation of mutant A-chain in the Golgi apparatus, glycosylation in the endoplasmic reticulum (ER) and appearance of A-chain in the cytosolic fraction was monitored. Introduction of an ER retrieval signal, a C-terminal KDEL sequence, into the A-chain increased the toxicity and resulted in more efficient glycosylation, indicating enhanced transport from Golgi to ER. Calcium depletion inhibited neither sulfation nor glycosylation but inhibited translocation and toxicity, suggesting that the toxin is translocated to the cytosol by the pathway used by misfolded proteins that are targeted to the proteasomes for degradation. Slightly acidified medium had a similar effect. The proteasome inhibitor, lactacystin, sensitized cells to ricin and increased the amount of ricin A-chain in the cytosol. Anti-Sec61alpha precipitated sulfated and glycosylated ricin A-chain, suggesting that retrograde toxin translocation involves Sec61p. The data indicate that retrograde translocation across the ER membrane is required for intoxication.     

The host cell chaperone Hsp90 is essential for translocation of the binary Clostridium botulinum C2 toxin into the cytosol

Clostridium botulinum C2 toxin is the prototype of the binary actin-ADP-ribosylating toxins and consists of the binding component C2II and the enzyme component C2I. The activated binding component C2IIa forms heptamers, which bind to carbohydrates on the cell surface and interact with the enzyme component C2I. This toxin complex is taken up by receptor-mediated endocytosis. In acidic endosomes, heptameric C2IIa forms pores and mediates the translocation of C2I into the cytosol. We report that the heat shock protein (Hsp) 90-specific inhibitors, geldanamycin or radicicol, block intoxication of Vero cells, rat astrocytes, and HeLa cells by C2 toxin. ADP-ribosylation of actin in the cytosol of toxin-treated cells revealed that less active C2I was translocated into the cytosol after treatment with Hsp90 inhibitors. Under control conditions, C2I was localized in the cytosol of toxin-treated rat astrocytes, whereas geldanamycin blocked the cytosolic distribution of C2I. At low extracellular pH (pH 4.5), which allows the direct translocation of C2I via C2IIa heptamers across the cell membrane into the cytosol, Hsp90 inhibitors retarded intoxication by C2I. Geldanamycin did not affect toxin binding, endocytosis, and pore formation by C2IIa. The ADP-ribosyltransferase activity of C2I was not affected by Hsp90 inhibitors in vitro. The cytotoxic actions of the actin-ADP-ribosylating Clostridium perfringens iota toxin and the Rho-ADP-ribosylating C2-C3 fusion toxin was similarly blocked by Hsp90 inhibitors. In contrast, radicicol and geldanamycin had no effect on anthrax lethal toxin-induced cytotoxicity of J774-A1 macrophage-like cells or on cytotoxic effects of the glucosylating Clostridium difficile toxin B in Vero cells. The data indicate that Hsp90 is essential for the membrane translocation of ADP-ribosylating toxins delivered by C2II.     

Membrane translocation of diphtheria toxin fragment A exploits early to late endosome trafficking machinery

After reaching early endosomes by receptor-mediated endocytosis, diphtheria toxin (DT) molecules have two possible fates. A large pool enters the degradative pathway whereas a few molecules become cytotoxic by translocating their catalytic fragment A (DTA) into the cytosol. Impairment of DT degradation by microtubule depolymerization does not block DT cytotoxicity. Therefore, DTA membrane translocation into the cytosol occurs from an endocytic compartment located upstream of late endosomes. Comparisons between early endosomes and endocytic carrier vesicles in a cell-free translocation assay have demonstrated that early endosomes are the earliest endocytic compartment from which DTA translocates. DTA translocation is ATP-dependent, requires early endosomal acidification, and is increased by the addition of cytosol. Cytosol-dependent DTA translocation is GTPγS-insensitive but is blocked by anti-βCOP antibodies.     

Endosomal proteolysis of diphtheria toxin without toxin translocation into the cytosol of rat liver in vivo

A detailed proteolysis study of internalized diphtheria toxin (DT) within rat liver endosomes was undertaken to determine whether DT-resistant species exhibit defects in toxin endocytosis, toxin activation by cellular enzymes or toxin translocation to its cytosolic target. Following administration of a saturating dose of wild-type DT or nontoxic mutant DT (mDT) to rats, rapid endocytosis of the intact 62-kDa toxin was observed coincident with the endosomal association of DT-A (low association) and DT-B (high association) subunits. Assessment of the subsequent post-endosomal fate of internalized mDT revealed a sustained endo-lysosomal transfer of the mDT-B subunit accompanied by a net decrease in intact mDT and mDT-A subunit throughout the endo-lysosomal apparatus. In vitro proteolysis of DT, using an endosomal lysate, was observed at both neutral and acidic pH, with the subsequent generation of DT-A and DT-B subunits (pH 7) or DT fragments with low ADP-ribosyltransferase activity (pH 4). Biochemical characterization revealed that the neutral endosomal DT-degrading activity was due to a novel luminal 70-kDa furin enzyme, whereas the aspartic acid protease cathepsin D (EC 3.4.23.5) was identified as being responsible for toxin degradation at acidic pH. Moreover, an absence of in vivo association of the DT-A subunit with cytosolic fractions was identified, as well as an absence of in vitro translocation of the DT-A subunit from cell-free endosomes into the external milieu. Based on these findings, we propose that, in rat, resistance to DT may originate from two different mechanisms: the ability of free DT-A subunits to be rapidly proteolyzed by acidic cathepsin D within the endosomal lumen, and/or the absence of DT translocation across the endosomal membrane, which may arise from the absence of a functional cytosolic translocation factor previously reported to participate in the export of DT from human endosomes.     

Extension of juxtamembrane domain of diphtheria toxin receptor arrests translocation of diphtheria toxin fragment A into cytosol

Diphtheria toxin (DT) binds to the EGF-like domain of the DT receptor (DTR), followed by internalization and translocation of the enzymatically active fragment A into the cytosol. The juxtamembrane domain (JM) of the DTR is the linker domain connecting the transmembrane and EGF-like domains. We constructed mutants of DTRs with altered JMs and studied their abilities for DT intoxication. Although DTR mutants with extended JMs showed normal DT binding activity, the cells expressing the mutants showed both reduced translocation of DT fragment A into the cytosol and reduced sensitivity to DT, when compared with cells expressing wild-type DTR. These results indicate that the JM contributes to DT intoxication by providing a space appropriate for the interaction of DT with the cell membrane. The present study also indicates that consideration of epitopes of an immunotoxins would be an important factor in the design of potent immunotoxins.     

Characterization of a transferrin-diphtheria toxin conjugate

We report here the synthesis and properties of a hybrid toxin prepared by covalently coupling diphtheria toxin to transferrin. The purified material contained two major hybrid protein species and was highly cytotoxic to mouse LMTK- cells in culture, reducing protein synthesis by 50% in 24 h at a concentration of 1 ng/ml. Cytotoxic activity was completely abolished in the presence of exogenous transferrin or anti-transferrin or anti-diphtheria toxin, thus demonstrating that the hybrid toxin was intoxicating cells via their transferrin receptors and that both the diphtheria toxin and transferrin components of the conjugate were necessary for activity. NH4Cl, a drug that elevates the pH within acidic intracellular vesicles, also blocked cytotoxic activity, suggesting that a low intravesicular pH was required for activity. The inhibitory effect of NH4Cl could be abolished by exposing toxin-treated cells to acidic culture medium, further implicating an acid-dependent step in the mechanism of the hybrid toxin action. Studies on the kinetics of intoxication also implied that endocytosis and exposure to a low pH within vesicles were necessary for cytotoxicity. Altogether, the results suggest that the transferrin-diphtheria toxin conjugate binds to transferrin receptors and is internalized into acidic endocytic vesicles. The enzymatic moiety of diphtheria toxin then apparently enters the cytosol in response to the low pH and subsequently arrests protein synthesis.     

Diphtheria toxin translocation across cellular membranes is regulated by sphingolipids

Diphtheria toxin is translocated across cellular membranes when receptor-bound toxin is exposed to low pH. To study the role of sphingolipids for toxin translocation, both a mutant cell line lacking the first enzyme in de novo sphingolipid synthesis, serine palmitoyltransferase, and a specific inhibitor of the same enzyme, myriocin, were used. The serine palmitoyltransferase-deficient cell line (LY-B) was found to be 10-15 times more sensitive to diphtheria toxin than the genetically complemented cell line (LY-B/cLCB1) and the wild-type cell line (CHO-K1), both when toxin translocation directly across the plasma membrane was induced by exposing cells with surface-bound toxin to low pH, and when the toxin followed its normal route via acidified endosomes into the cytosol. Toxin binding was similar in these three cell lines. Furthermore, inhibition of serine palmitoyltransferase activity by addition of myriocin sensitized the two control cell lines (LY-B/cLCB1 and CHO-K1) to diphtheria toxin, whereas, as expected, no effect was observed in cells lacking serine palmitoyltransferase (LY-B). In conclusion, diphtheria toxin translocation is facilitated by depletion of membrane sphingolipids.     

Role of lipids in the retrograde pathway of ricin intoxication

The plant toxin ricin binds to both glycosphingolipids and glycoproteins with terminal galactose and is transported to the Golgi apparatus in a cholesterol-dependent manner. To explore the question of whether glycosphingolipid binding of ricin or glycosphingolipid synthesis is essential for transport of ricin from the plasma membrane to the Golgi apparatus, retrogradely to the endoplasmic reticulum or for translocation of the toxin to the cytosol, we have investigated the effect of ricin and the intracellular transport of this toxin in a glycosphingolipid-deficient mouse melanoma cell line (GM95), in the same cell line transfected with ceramide glucosyltransferase to restore glycosphingolipid synthesis (GM95-CGlcT-KKVK) and in the parental cell line (MEB4). Ricin transport to the Golgi apparatus was monitored by quantifying sulfation of a modified ricin molecule, and toxicity was studied by measuring protein synthesis. The data reveal that ricin is transported retrogradely to the Golgi apparatus and to the endoplasmic reticulum and translocated to the cytosol equally well and apparently at the same rate in cells with and without glycosphingolipids. Importantly cholesterol depletion reduced endosome to Golgi transport of ricin even in cells without glycosphingolipids, demonstrating that cholesterol is required for Golgi transport of ricin bound to glycoproteins. The rate of retrograde transport of ricin was increased strongly by monensin and the lag time for intoxication was reduced both in cells with and in those without glycosphingolipids. In conclusion, neither glycosphingolipid synthesis nor binding of ricin to glycosphingolipids is essential for cholesterol-dependent retrograde transport of ricin. Binding of ricin to glycoproteins is sufficient for all transport steps required for ricin intoxication.